SlideShare a Scribd company logo

Distributed deadlock

Md. Mahedi Mahfuj
Md. Mahedi Mahfuj
Technology
1 of 8
Download to read offline
DISTRIBUTED DEADLOCK Abstract: A deadlock is a condition in a system where a process cannot proceed because it needs to obtain a resource held by another process but it itself is holding a resource that the other process needs. In a system of processes which communicate only with a single central agent, deadlock can be detected easily because the central agent has complete information about every process. Deadlock detection is more difficult in systems where there is no such central agent and processes may communicate directly with one another. If we could assume that message communication is instantaneous, or if we could place certain restrictions on message delays, deadlock detection would become simpler. However, the only realistic general assumption we can make is that message delays are arbitrary but finite. Deadlock is a fundamental problem in distributed systems. A process may request resources in any order, which may not be known a priori and a process can request resource while holding others. If the sequence of the allocations of resources to the processes is not controlled, deadlocks can occur. Moreover, a deadlock is a state where a set of processes request resources that are held by other processes in the set. Types of Deadlock: Two types of deadlock can be considered:  Communication Deadlock  Resource Deadlock Communication deadlock occurs when process A is trying to send a message to process B, which is trying to send a message to process C which is trying to send a message to A. Resource deadlock occurs when processes are trying to get exclusive access to devices, files, locks, servers, or other resources. We will not differentiate between these types of deadlock since we can consider communication channels to be resources without loss of generality. Conditions for Deadlock: Four conditions have to be met for a deadlock to occur in a system: 1. Mutual exclusion A resource can be held by at most one process. 2. Hold and wait Processes that already hold resources can wait for another resource. 1|Page
DISTRIBUTED DEADLOCK 3. Non-preemption A resource, once granted, cannot be taken away. 4. Circular wait Two or more processes are waiting for resources held by one of the other processes. Resource allocation can be represented by directed graphs: P1 R1 means that resource R1 is allocated to process P1. P1 R1 means that resource R1 is requested by process P1. Deadlock is present when the graph has cycles. An example is shown in Figure 1. Figure 1: Deadlock. Wait for Graph: The state of the system can be modeled by directed graph, called a wait for graph (WFG). In a WFG, nodes are processes and there is a directed edge from node P1 to mode P2 if P1 is blocked and is waiting for P2 to release some resource. A system is deadlocked if and only if there exists a directed cycle or knot in the WFG.A Figure 1 shows a WFG, where process P11 of site 1 has an edge to process P21 of site 1 and P32 of site 2 is waiting for a resource which is currently held by process P21. At the same time process P32 is waiting on process P33 to release a resource. If P21 is waiting on process P11, then processes P11, P32 and P21 form a cycle and all the four processes are involved in a deadlock depending upon the request model. 2|Page
DISTRIBUTED DEADLOCK Figure 2: A Wait-for-Graph. Handling Deadlocks in Distributed Systems: Deadlocks in distributed systems are similar to deadlocks in centralized systems. In centralized systems, we have one operating system that can oversee resource allocation and know whether deadlocks are present. With distributed processes and resources it becomes harder to detect, avoid, and prevent deadlocks. Several strategies can be used to handle deadlocks: Ignore: We can ignore the problem. This is one of the most popular solutions. Detect: We can allow deadlocks to occur, then detect that we have a deadlock in the system, and then deal with the deadlock. Prevent: We can place constraints on resource allocation to make deadlocks impossible. Avoid: We can choose resource allocation carefully and make deadlocks impossible. 3|Page
DISTRIBUTED DEADLOCK Deadlock avoidance is never used (either in distributed or centralized systems). The problem with deadlock avoidance is that the algorithm will need to know resource usage requirements in advance so as to schedule them properly. Whereas, the first of these is trivially simple. The other two are described in details: Deadlock Detection: General methods for preventing or avoiding deadlocks can be difficult to find. Detecting a deadlock condition is generally easier. When a deadlock is detected, it has to be broken. This is traditionally done by killing one or more processes that contribute to the deadlock. Unfortunately, this can lead to annoyed users. When a deadlock is detected in a system that is based on atomic transactions, it is resolved by aborting one or more transactions. But transactions have been designed to withstand being aborted. Consequences of killing a process in a transactional system are less severe. Centralized: Centralized deadlock detection attempts to imitate the nondistributed algorithm through a central coordinator. Each machine is responsible for maintaining a resource graph for its processes and resources. A central coordinator maintains the resource utilization graph for the entire system. This graph is the union of the individual graphs. If this coordinator detects a cycle, it kills off one process to break the deadlock. In the non-distributed case, all the information on resource usage lives on one system and the graph may be constructed on that system. In the distributed case, the individual sub graphs have to be propagated to a central coordinator. A message can be sent each time an arc is added or deleted. If optimization is needed, a list of added or deleted arcs can be sent periodically to reduce the overall number of messages sent. Here is an example. Suppose machine A has a process P0, which holds the resource S and wants resource R, which is held by P1. The local graph on A is shown in Figure 2. Another machine, machine B has a process P2, which is holding resource T and wants resource S. Its local graph is shown in Figure 3. Both of these machines send their graphs to the central coordinator, which maintains the union (Figure 3). All is well. There are no cycles and hence no deadlocks. Now two events occur. Process P1 releases resource R and asks machine B for resource T. Two messages are sent to the coordinator: Message 1 (from machine A): “releasing R” Message 2 (from machine B): “waiting for T” This should cause no problems (no deadlock). However, if message 2 arrives first, the coordinator would then construct the graph in Figure 4 and detect a deadlock. Such a condition is known as false deadlock. A way to fix this is to use Lamport’s algorithm to impose global time ordering on all machines. Alternatively, if the coordinator suspects deadlock, it can send a reliable message to every machine asking whether it has any release 4|Page
DISTRIBUTED DEADLOCK messages. Each machine will then respond with either a release message or a negative acknowledgement to acknowledge receipt of the message. Figure 3: Centralized Deadlock Detection. Figure 4: False Deadlock. 5|Page
DISTRIBUTED DEADLOCK Distributed: An algorithm for detecting deadlocks in a distributed system was proposed by Chaudy, Misra, and Haas in 1983. It allows that processes to request multiple resources at once (this speeds up the growing phase). Some processes may wait for resources (either local or remote). Cross-machine arcs make looking for cycles (detecting deadlock) hard. The algorithm works this way: When a process has to wait for a resource, a probe message is sent to the process holding the resource. The probe message contains three components: the process that blocked, the process that is sending the request, and the destination. Initially, the first two components will be the same. When a process receives the probe: if the process itself is waiting on a resource, it updates the sending and destination fields of the message and forwards it to the resource holder. If it is waiting on multiple resources, a message is sent to each process holding the resources. This process continues as long as processes are waiting for resources. If the originator gets a message and sees its own process number in the blocked field of the message, it knows that a cycle has been taken and deadlock exists. In this case, some process (transaction) will have to die. The sender may choose to commit suicide or a ring election algorithm may be used to determine an alternate victim (e.g., youngest process, oldest process). Deadlock prevention An alternative to detecting deadlocks is to design a system so that deadlock is impossible. One way of accomplishing this is to obtain a global timestamp for every transaction (so that no two transactions get the same timestamp). When one process is about to block waiting for a resource that another process is using, check which of the two processes has a younger timestamp and give priority to the older process. If a younger process is using the resource, then the older process (that wants the resource) waits. If an older process is holding the resource, the younger process (that wants the resource) kills itself. This forces the resource utilization graph to be directed from older to younger processes, making cycles impossible. This algorithm is known as the wait-die algorithm (Figure 5). An alternative method by which resource request cycles may be avoided is to have an old process preempt (kill) the younger process that holds a resource. If a younger process wants a resource that an older one is using, then it waits until the old process is done. In this case, the graph flows from young to old and cycles are again impossible. This variant is called the wound-wait algorithm (Figure 6). 6|Page
DISTRIBUTED DEADLOCK Figure 5: Wait-die Algorithm. Figure 6: Wound-wait Algorithm. 7|Page
DISTRIBUTED DEADLOCK Conclusion: Deadlock is the state of permanent blocking of a set of processes each of which is waiting for an event that only another process in the set can cause. However, handling of deadlocks in distributed systems is more complex than in centralized systems because the resources, the processes and other relevant information are scattered on different nodes of the system. ……………………………………………………………….X…………………………………………………………………… 8|Page

Recommended

Optimistic concurrency control in Distributed Systems
Optimistic concurrency control in Distributed SystemsOptimistic concurrency control in Distributed Systems
Optimistic concurrency control in Distributed Systems
mridul mishra
 
Agreement Protocols, distributed File Systems, Distributed Shared Memory
Agreement Protocols, distributed File Systems, Distributed Shared MemoryAgreement Protocols, distributed File Systems, Distributed Shared Memory
Agreement Protocols, distributed File Systems, Distributed Shared Memory
SHIKHA GAUTAM
 
Locks In Disributed Systems
Locks In Disributed SystemsLocks In Disributed Systems
Locks In Disributed Systems
mridul mishra
 
Distributed file system
Distributed file systemDistributed file system
Distributed file system
Anamika Singh
 
Message passing in Distributed Computing Systems
Message passing in Distributed Computing SystemsMessage passing in Distributed Computing Systems
Message passing in Distributed Computing Systems
Alagappa Govt Arts College, Karaikudi
 
Physical and Logical Clocks
Physical and Logical ClocksPhysical and Logical Clocks
Physical and Logical Clocks
Dilum Bandara
 
Communication primitives
Communication primitivesCommunication primitives
Communication primitives
Student
 
File models and file accessing models
File models and file accessing modelsFile models and file accessing models
File models and file accessing models
ishmecse13
 

Recommended

Optimistic concurrency control in Distributed Systems
Optimistic concurrency control in Distributed SystemsOptimistic concurrency control in Distributed Systems
Optimistic concurrency control in Distributed Systems
mridul mishra
 
Agreement Protocols, distributed File Systems, Distributed Shared Memory
Agreement Protocols, distributed File Systems, Distributed Shared MemoryAgreement Protocols, distributed File Systems, Distributed Shared Memory
Agreement Protocols, distributed File Systems, Distributed Shared Memory
SHIKHA GAUTAM
 
Locks In Disributed Systems
Locks In Disributed SystemsLocks In Disributed Systems
Locks In Disributed Systems
mridul mishra
 
Distributed file system
Distributed file systemDistributed file system
Distributed file system
Anamika Singh
 
Message passing in Distributed Computing Systems
Message passing in Distributed Computing SystemsMessage passing in Distributed Computing Systems
Message passing in Distributed Computing Systems
Alagappa Govt Arts College, Karaikudi
 
Physical and Logical Clocks
Physical and Logical ClocksPhysical and Logical Clocks
Physical and Logical Clocks
Dilum Bandara
 
Communication primitives
Communication primitivesCommunication primitives
Communication primitives
Student
 
File models and file accessing models
File models and file accessing modelsFile models and file accessing models
File models and file accessing models
ishmecse13
 
Communications is distributed systems
Communications is distributed systemsCommunications is distributed systems
Communications is distributed systems
SHATHAN
 
distributed Computing system model
distributed Computing system modeldistributed Computing system model
distributed Computing system model
Harshad Umredkar
 
Fault tolerance in distributed systems
Fault tolerance in distributed systemsFault tolerance in distributed systems
Fault tolerance in distributed systems
sumitjain2013
 
Clock synchronization in distributed system
Clock synchronization in distributed systemClock synchronization in distributed system
Clock synchronization in distributed system
Sunita Sahu
 
Distributed Mutual exclusion algorithms
Distributed Mutual exclusion algorithmsDistributed Mutual exclusion algorithms
Distributed Mutual exclusion algorithms
MNM Jain Engineering College
 
Replication in Distributed Systems
Replication in Distributed SystemsReplication in Distributed Systems
Replication in Distributed Systems
Kavya Barnadhya Hazarika
 
Introduction to Distributed System
Introduction to Distributed SystemIntroduction to Distributed System
Introduction to Distributed System
Sunita Sahu
 
Peer to Peer services and File systems
Peer to Peer services and File systemsPeer to Peer services and File systems
Peer to Peer services and File systems
MNM Jain Engineering College
 
distributed shared memory
distributed shared memory distributed shared memory
distributed shared memory
Ashish Kumar
 
Distributed shred memory architecture
Distributed shred memory architectureDistributed shred memory architecture
Distributed shred memory architecture
Maulik Togadiya
 
Distributed concurrency control
Distributed concurrency controlDistributed concurrency control
Distributed concurrency control
Binte fatima
 
Processes and Processors in Distributed Systems
Processes and Processors in Distributed SystemsProcesses and Processors in Distributed Systems
Processes and Processors in Distributed Systems
Dr Sandeep Kumar Poonia
 
Concurrency control
Concurrency controlConcurrency control
Concurrency control
Subhasish Pati
 
Levels of Virtualization.docx
Levels of Virtualization.docxLevels of Virtualization.docx
Levels of Virtualization.docx
kumari36
 
Process Management-Process Migration
Process Management-Process MigrationProcess Management-Process Migration
Process Management-Process Migration
MNM Jain Engineering College
 
Logical Clocks (Distributed computing)
Logical Clocks (Distributed computing)Logical Clocks (Distributed computing)
Logical Clocks (Distributed computing)
Sri Prasanna
 
Operating system 24 mutex locks and semaphores
Operating system 24 mutex locks and semaphoresOperating system 24 mutex locks and semaphores
Operating system 24 mutex locks and semaphores
Vaibhav Khanna
 
Distributed Transactions(flat and nested) and Atomic Commit Protocols
Distributed Transactions(flat and nested) and Atomic Commit ProtocolsDistributed Transactions(flat and nested) and Atomic Commit Protocols
Distributed Transactions(flat and nested) and Atomic Commit Protocols
Sachin Chauhan
 
Synchronization in distributed computing
Synchronization in distributed computingSynchronization in distributed computing
Synchronization in distributed computing
SVijaylakshmi
 
8. mutual exclusion in Distributed Operating Systems
8. mutual exclusion in Distributed Operating Systems8. mutual exclusion in Distributed Operating Systems
8. mutual exclusion in Distributed Operating Systems
Dr Sandeep Kumar Poonia
 
Deadlock in distribute system by saeed siddik
Deadlock in distribute system by saeed siddikDeadlock in distribute system by saeed siddik
Deadlock in distribute system by saeed siddik
Saeed Siddik
 
Deadlock detection
Deadlock detectionDeadlock detection
Deadlock detection
Nadia Nahar
 

More Related Content

What's hot

Fault tolerance in distributed systems
Fault tolerance in distributed systemsFault tolerance in distributed systems
Fault tolerance in distributed systems
sumitjain2013
 
distributed shared memory
distributed shared memory distributed shared memory
distributed shared memory
Ashish Kumar
 
Logical Clocks (Distributed computing)
Logical Clocks (Distributed computing)Logical Clocks (Distributed computing)
Logical Clocks (Distributed computing)
Sri Prasanna
 
Operating system 24 mutex locks and semaphores
Operating system 24 mutex locks and semaphoresOperating system 24 mutex locks and semaphores
Operating system 24 mutex locks and semaphores
Vaibhav Khanna
 

What's hot (20)

Communications is distributed systems
Communications is distributed systemsCommunications is distributed systems
Communications is distributed systems
 
distributed Computing system model
distributed Computing system modeldistributed Computing system model
distributed Computing system model
 
Fault tolerance in distributed systems
Fault tolerance in distributed systemsFault tolerance in distributed systems
Fault tolerance in distributed systems
 
Clock synchronization in distributed system
Clock synchronization in distributed systemClock synchronization in distributed system
Clock synchronization in distributed system
 
Distributed Mutual exclusion algorithms
Distributed Mutual exclusion algorithmsDistributed Mutual exclusion algorithms
Distributed Mutual exclusion algorithms
 
Replication in Distributed Systems
Replication in Distributed SystemsReplication in Distributed Systems
Replication in Distributed Systems
 
Introduction to Distributed System
Introduction to Distributed SystemIntroduction to Distributed System
Introduction to Distributed System
 
Peer to Peer services and File systems
Peer to Peer services and File systemsPeer to Peer services and File systems
Peer to Peer services and File systems
 
distributed shared memory
distributed shared memory distributed shared memory
distributed shared memory
 
Distributed shred memory architecture
Distributed shred memory architectureDistributed shred memory architecture
Distributed shred memory architecture
 
Distributed concurrency control
Distributed concurrency controlDistributed concurrency control
Distributed concurrency control
 
Processes and Processors in Distributed Systems
Processes and Processors in Distributed SystemsProcesses and Processors in Distributed Systems
Processes and Processors in Distributed Systems
 
Concurrency control
Concurrency controlConcurrency control
Concurrency control
 
Levels of Virtualization.docx
Levels of Virtualization.docxLevels of Virtualization.docx
Levels of Virtualization.docx
 
Process Management-Process Migration
Process Management-Process MigrationProcess Management-Process Migration
Process Management-Process Migration
 
Logical Clocks (Distributed computing)
Logical Clocks (Distributed computing)Logical Clocks (Distributed computing)
Logical Clocks (Distributed computing)
 
Operating system 24 mutex locks and semaphores
Operating system 24 mutex locks and semaphoresOperating system 24 mutex locks and semaphores
Operating system 24 mutex locks and semaphores
 
Distributed Transactions(flat and nested) and Atomic Commit Protocols
Distributed Transactions(flat and nested) and Atomic Commit ProtocolsDistributed Transactions(flat and nested) and Atomic Commit Protocols
Distributed Transactions(flat and nested) and Atomic Commit Protocols
 
Synchronization in distributed computing
Synchronization in distributed computingSynchronization in distributed computing
Synchronization in distributed computing
 
8. mutual exclusion in Distributed Operating Systems
8. mutual exclusion in Distributed Operating Systems8. mutual exclusion in Distributed Operating Systems
8. mutual exclusion in Distributed Operating Systems
 

Similar to Distributed deadlock

Deadlock in distribute system by saeed siddik
Deadlock in distribute system by saeed siddikDeadlock in distribute system by saeed siddik
Deadlock in distribute system by saeed siddik
Saeed Siddik
 
Os presentation final.pptxjjjjjdakajwsjjdhdfjff
Os presentation final.pptxjjjjjdakajwsjjdhdfjffOs presentation final.pptxjjjjjdakajwsjjdhdfjff
Os presentation final.pptxjjjjjdakajwsjjdhdfjff
ZeelGoyani
 
Process Synchronization And Deadlocks
Process Synchronization And DeadlocksProcess Synchronization And Deadlocks
Process Synchronization And Deadlocks
tech2click
 

Similar to Distributed deadlock (20)

Deadlock in distribute system by saeed siddik
Deadlock in distribute system by saeed siddikDeadlock in distribute system by saeed siddik
Deadlock in distribute system by saeed siddik
 
Deadlock detection
Deadlock detectionDeadlock detection
Deadlock detection
 
Deadlock and memory management -- Operating System
Deadlock and memory management -- Operating SystemDeadlock and memory management -- Operating System
Deadlock and memory management -- Operating System
 
Operating system Deadlock
Operating system DeadlockOperating system Deadlock
Operating system Deadlock
 
Os presentation final.pptxjjjjjdakajwsjjdhdfjff
Os presentation final.pptxjjjjjdakajwsjjdhdfjffOs presentation final.pptxjjjjjdakajwsjjdhdfjff
Os presentation final.pptxjjjjjdakajwsjjdhdfjff
 
Module3
Module3Module3
Module3
 
Deadlocks prefinal
Deadlocks prefinalDeadlocks prefinal
Deadlocks prefinal
 
Deadlocksprefinal 161014115456
Deadlocksprefinal 161014115456Deadlocksprefinal 161014115456
Deadlocksprefinal 161014115456
 
Unit iv: Deadlocks
Unit iv: DeadlocksUnit iv: Deadlocks
Unit iv: Deadlocks
 
Deadlock
DeadlockDeadlock
Deadlock
 
Deadlocks final
Deadlocks finalDeadlocks final
Deadlocks final
 
Process Synchronization And Deadlocks
Process Synchronization And DeadlocksProcess Synchronization And Deadlocks
Process Synchronization And Deadlocks
 
operating system
operating systemoperating system
operating system
 
operating system
operating systemoperating system
operating system
 
Rdbms
RdbmsRdbms
Rdbms
 
Deadlockproj.pptx
Deadlockproj.pptxDeadlockproj.pptx
Deadlockproj.pptx
 
Os module 2 d
Os module 2 dOs module 2 d
Os module 2 d
 
Operating system - Deadlock
Operating system - DeadlockOperating system - Deadlock
Operating system - Deadlock
 
Process coordination
Process coordinationProcess coordination
Process coordination
 
Deadlock in Operating System
Deadlock in Operating SystemDeadlock in Operating System
Deadlock in Operating System
 

More from Md. Mahedi Mahfuj

Bengali optical character recognition system
Bengali optical character recognition systemBengali optical character recognition system
Bengali optical character recognition system
Md. Mahedi Mahfuj
 
Parallel computing chapter 3
Parallel computing chapter 3Parallel computing chapter 3
Parallel computing chapter 3
Md. Mahedi Mahfuj
 
Parallel computing chapter 2
Parallel computing chapter 2Parallel computing chapter 2
Parallel computing chapter 2
Md. Mahedi Mahfuj
 
Advanced computer architecture
Advanced computer architectureAdvanced computer architecture
Advanced computer architecture
Md. Mahedi Mahfuj
 
Database management system chapter16
Database management system chapter16Database management system chapter16
Database management system chapter16
Md. Mahedi Mahfuj
 
Database management system chapter15
Database management system chapter15Database management system chapter15
Database management system chapter15
Md. Mahedi Mahfuj
 
Database management system chapter12
Database management system chapter12Database management system chapter12
Database management system chapter12
Md. Mahedi Mahfuj
 
Strategies in job search process
Strategies in job search processStrategies in job search process
Strategies in job search process
Md. Mahedi Mahfuj
 

More from Md. Mahedi Mahfuj (20)

Bengali optical character recognition system
Bengali optical character recognition systemBengali optical character recognition system
Bengali optical character recognition system
 
Parallel computing chapter 3
Parallel computing chapter 3Parallel computing chapter 3
Parallel computing chapter 3
 
Parallel computing chapter 2
Parallel computing chapter 2Parallel computing chapter 2
Parallel computing chapter 2
 
Parallel computing(2)
Parallel computing(2)Parallel computing(2)
Parallel computing(2)
 
Parallel computing(1)
Parallel computing(1)Parallel computing(1)
Parallel computing(1)
 
Message passing interface
Message passing interfaceMessage passing interface
Message passing interface
 
Advanced computer architecture
Advanced computer architectureAdvanced computer architecture
Advanced computer architecture
 
Parallel searching
Parallel searchingParallel searching
Parallel searching
 
Clustering manual
Clustering manualClustering manual
Clustering manual
 
Matrix multiplication graph
Matrix multiplication graphMatrix multiplication graph
Matrix multiplication graph
 
Strategy pattern
Strategy patternStrategy pattern
Strategy pattern
 
Observer pattern
Observer patternObserver pattern
Observer pattern
 
Mediator pattern
Mediator patternMediator pattern
Mediator pattern
 
Database management system chapter16
Database management system chapter16Database management system chapter16
Database management system chapter16
 
Database management system chapter15
Database management system chapter15Database management system chapter15
Database management system chapter15
 
Database management system chapter12
Database management system chapter12Database management system chapter12
Database management system chapter12
 
Strategies in job search process
Strategies in job search processStrategies in job search process
Strategies in job search process
 
Report writing(short)
Report writing(short)Report writing(short)
Report writing(short)
 
Report writing(long)
Report writing(long)Report writing(long)
Report writing(long)
 
Job search_resume
Job search_resumeJob search_resume
Job search_resume
 

Recently uploaded

EIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptx
EIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptxEIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptx
EIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptx
Earley Information Science
 
08448380779 Call Girls In Diplomatic Enclave Women Seeking Men
08448380779 Call Girls In Diplomatic Enclave Women Seeking Men08448380779 Call Girls In Diplomatic Enclave Women Seeking Men
08448380779 Call Girls In Diplomatic Enclave Women Seeking Men
Delhi Call girls
 
From Event to Action: Accelerate Your Decision Making with Real-Time Automation
From Event to Action: Accelerate Your Decision Making with Real-Time AutomationFrom Event to Action: Accelerate Your Decision Making with Real-Time Automation
From Event to Action: Accelerate Your Decision Making with Real-Time Automation
Safe Software
 
A Year of the Servo Reboot: Where Are We Now?
A Year of the Servo Reboot: Where Are We Now?A Year of the Servo Reboot: Where Are We Now?
A Year of the Servo Reboot: Where Are We Now?
Igalia
 
Breaking the Kubernetes Kill Chain: Host Path Mount
Breaking the Kubernetes Kill Chain: Host Path MountBreaking the Kubernetes Kill Chain: Host Path Mount
Breaking the Kubernetes Kill Chain: Host Path Mount
Puma Security, LLC
 
08448380779 Call Girls In Friends Colony Women Seeking Men
08448380779 Call Girls In Friends Colony Women Seeking Men08448380779 Call Girls In Friends Colony Women Seeking Men
08448380779 Call Girls In Friends Colony Women Seeking Men
Delhi Call girls
 

Recently uploaded (20)

Real Time Object Detection Using Open CV
Real Time Object Detection Using Open CVReal Time Object Detection Using Open CV
Real Time Object Detection Using Open CV
 
Data Cloud, More than a CDP by Matt Robison
Data Cloud, More than a CDP by Matt RobisonData Cloud, More than a CDP by Matt Robison
Data Cloud, More than a CDP by Matt Robison
 
EIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptx
EIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptxEIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptx
EIS-Webinar-Prompt-Knowledge-Eng-2024-04-08.pptx
 
08448380779 Call Girls In Diplomatic Enclave Women Seeking Men
08448380779 Call Girls In Diplomatic Enclave Women Seeking Men08448380779 Call Girls In Diplomatic Enclave Women Seeking Men
08448380779 Call Girls In Diplomatic Enclave Women Seeking Men
 
From Event to Action: Accelerate Your Decision Making with Real-Time Automation
From Event to Action: Accelerate Your Decision Making with Real-Time AutomationFrom Event to Action: Accelerate Your Decision Making with Real-Time Automation
From Event to Action: Accelerate Your Decision Making with Real-Time Automation
 
A Year of the Servo Reboot: Where Are We Now?
A Year of the Servo Reboot: Where Are We Now?A Year of the Servo Reboot: Where Are We Now?
A Year of the Servo Reboot: Where Are We Now?
 
Exploring the Future Potential of AI-Enabled Smartphone Processors
Exploring the Future Potential of AI-Enabled Smartphone ProcessorsExploring the Future Potential of AI-Enabled Smartphone Processors
Exploring the Future Potential of AI-Enabled Smartphone Processors
 
Breaking the Kubernetes Kill Chain: Host Path Mount
Breaking the Kubernetes Kill Chain: Host Path MountBreaking the Kubernetes Kill Chain: Host Path Mount
Breaking the Kubernetes Kill Chain: Host Path Mount
 
08448380779 Call Girls In Friends Colony Women Seeking Men
08448380779 Call Girls In Friends Colony Women Seeking Men08448380779 Call Girls In Friends Colony Women Seeking Men
08448380779 Call Girls In Friends Colony Women Seeking Men
 
Powerful Google developer tools for immediate impact! (2023-24 C)
Powerful Google developer tools for immediate impact! (2023-24 C)Powerful Google developer tools for immediate impact! (2023-24 C)
Powerful Google developer tools for immediate impact! (2023-24 C)
 
A Call to Action for Generative AI in 2024
A Call to Action for Generative AI in 2024A Call to Action for Generative AI in 2024
A Call to Action for Generative AI in 2024
 
What Are The Drone Anti-jamming Systems Technology?
What Are The Drone Anti-jamming Systems Technology?What Are The Drone Anti-jamming Systems Technology?
What Are The Drone Anti-jamming Systems Technology?
 
A Domino Admins Adventures (Engage 2024)
A Domino Admins Adventures (Engage 2024)A Domino Admins Adventures (Engage 2024)
A Domino Admins Adventures (Engage 2024)
 
Apidays Singapore 2024 - Building Digital Trust in a Digital Economy by Veron...
Apidays Singapore 2024 - Building Digital Trust in a Digital Economy by Veron...Apidays Singapore 2024 - Building Digital Trust in a Digital Economy by Veron...
Apidays Singapore 2024 - Building Digital Trust in a Digital Economy by Veron...
 
Advantages of Hiring UIUX Design Service Providers for Your Business
Advantages of Hiring UIUX Design Service Providers for Your BusinessAdvantages of Hiring UIUX Design Service Providers for Your Business
Advantages of Hiring UIUX Design Service Providers for Your Business
 
Axa Assurance Maroc - Insurer Innovation Award 2024
Axa Assurance Maroc - Insurer Innovation Award 2024Axa Assurance Maroc - Insurer Innovation Award 2024
Axa Assurance Maroc - Insurer Innovation Award 2024
 
GenCyber Cyber Security Day Presentation
GenCyber Cyber Security Day PresentationGenCyber Cyber Security Day Presentation
GenCyber Cyber Security Day Presentation
 
04-2024-HHUG-Sales-and-Marketing-Alignment.pptx
04-2024-HHUG-Sales-and-Marketing-Alignment.pptx04-2024-HHUG-Sales-and-Marketing-Alignment.pptx
04-2024-HHUG-Sales-and-Marketing-Alignment.pptx
 
The 7 Things I Know About Cyber Security After 25 Years | April 2024
The 7 Things I Know About Cyber Security After 25 Years | April 2024The 7 Things I Know About Cyber Security After 25 Years | April 2024
The 7 Things I Know About Cyber Security After 25 Years | April 2024
 
Boost Fertility New Invention Ups Success Rates.pdf
Boost Fertility New Invention Ups Success Rates.pdfBoost Fertility New Invention Ups Success Rates.pdf
Boost Fertility New Invention Ups Success Rates.pdf
 

Distributed deadlock

  • 1. DISTRIBUTED DEADLOCK Abstract: A deadlock is a condition in a system where a process cannot proceed because it needs to obtain a resource held by another process but it itself is holding a resource that the other process needs. In a system of processes which communicate only with a single central agent, deadlock can be detected easily because the central agent has complete information about every process. Deadlock detection is more difficult in systems where there is no such central agent and processes may communicate directly with one another. If we could assume that message communication is instantaneous, or if we could place certain restrictions on message delays, deadlock detection would become simpler. However, the only realistic general assumption we can make is that message delays are arbitrary but finite. Deadlock is a fundamental problem in distributed systems. A process may request resources in any order, which may not be known a priori and a process can request resource while holding others. If the sequence of the allocations of resources to the processes is not controlled, deadlocks can occur. Moreover, a deadlock is a state where a set of processes request resources that are held by other processes in the set. Types of Deadlock: Two types of deadlock can be considered:  Communication Deadlock  Resource Deadlock Communication deadlock occurs when process A is trying to send a message to process B, which is trying to send a message to process C which is trying to send a message to A. Resource deadlock occurs when processes are trying to get exclusive access to devices, files, locks, servers, or other resources. We will not differentiate between these types of deadlock since we can consider communication channels to be resources without loss of generality. Conditions for Deadlock: Four conditions have to be met for a deadlock to occur in a system: 1. Mutual exclusion A resource can be held by at most one process. 2. Hold and wait Processes that already hold resources can wait for another resource. 1|Page
  • 2. DISTRIBUTED DEADLOCK 3. Non-preemption A resource, once granted, cannot be taken away. 4. Circular wait Two or more processes are waiting for resources held by one of the other processes. Resource allocation can be represented by directed graphs: P1 R1 means that resource R1 is allocated to process P1. P1 R1 means that resource R1 is requested by process P1. Deadlock is present when the graph has cycles. An example is shown in Figure 1. Figure 1: Deadlock. Wait for Graph: The state of the system can be modeled by directed graph, called a wait for graph (WFG). In a WFG, nodes are processes and there is a directed edge from node P1 to mode P2 if P1 is blocked and is waiting for P2 to release some resource. A system is deadlocked if and only if there exists a directed cycle or knot in the WFG.A Figure 1 shows a WFG, where process P11 of site 1 has an edge to process P21 of site 1 and P32 of site 2 is waiting for a resource which is currently held by process P21. At the same time process P32 is waiting on process P33 to release a resource. If P21 is waiting on process P11, then processes P11, P32 and P21 form a cycle and all the four processes are involved in a deadlock depending upon the request model. 2|Page
  • 3. DISTRIBUTED DEADLOCK Figure 2: A Wait-for-Graph. Handling Deadlocks in Distributed Systems: Deadlocks in distributed systems are similar to deadlocks in centralized systems. In centralized systems, we have one operating system that can oversee resource allocation and know whether deadlocks are present. With distributed processes and resources it becomes harder to detect, avoid, and prevent deadlocks. Several strategies can be used to handle deadlocks: Ignore: We can ignore the problem. This is one of the most popular solutions. Detect: We can allow deadlocks to occur, then detect that we have a deadlock in the system, and then deal with the deadlock. Prevent: We can place constraints on resource allocation to make deadlocks impossible. Avoid: We can choose resource allocation carefully and make deadlocks impossible. 3|Page
  • 4. DISTRIBUTED DEADLOCK Deadlock avoidance is never used (either in distributed or centralized systems). The problem with deadlock avoidance is that the algorithm will need to know resource usage requirements in advance so as to schedule them properly. Whereas, the first of these is trivially simple. The other two are described in details: Deadlock Detection: General methods for preventing or avoiding deadlocks can be difficult to find. Detecting a deadlock condition is generally easier. When a deadlock is detected, it has to be broken. This is traditionally done by killing one or more processes that contribute to the deadlock. Unfortunately, this can lead to annoyed users. When a deadlock is detected in a system that is based on atomic transactions, it is resolved by aborting one or more transactions. But transactions have been designed to withstand being aborted. Consequences of killing a process in a transactional system are less severe. Centralized: Centralized deadlock detection attempts to imitate the nondistributed algorithm through a central coordinator. Each machine is responsible for maintaining a resource graph for its processes and resources. A central coordinator maintains the resource utilization graph for the entire system. This graph is the union of the individual graphs. If this coordinator detects a cycle, it kills off one process to break the deadlock. In the non-distributed case, all the information on resource usage lives on one system and the graph may be constructed on that system. In the distributed case, the individual sub graphs have to be propagated to a central coordinator. A message can be sent each time an arc is added or deleted. If optimization is needed, a list of added or deleted arcs can be sent periodically to reduce the overall number of messages sent. Here is an example. Suppose machine A has a process P0, which holds the resource S and wants resource R, which is held by P1. The local graph on A is shown in Figure 2. Another machine, machine B has a process P2, which is holding resource T and wants resource S. Its local graph is shown in Figure 3. Both of these machines send their graphs to the central coordinator, which maintains the union (Figure 3). All is well. There are no cycles and hence no deadlocks. Now two events occur. Process P1 releases resource R and asks machine B for resource T. Two messages are sent to the coordinator: Message 1 (from machine A): “releasing R” Message 2 (from machine B): “waiting for T” This should cause no problems (no deadlock). However, if message 2 arrives first, the coordinator would then construct the graph in Figure 4 and detect a deadlock. Such a condition is known as false deadlock. A way to fix this is to use Lamport’s algorithm to impose global time ordering on all machines. Alternatively, if the coordinator suspects deadlock, it can send a reliable message to every machine asking whether it has any release 4|Page
  • 5. DISTRIBUTED DEADLOCK messages. Each machine will then respond with either a release message or a negative acknowledgement to acknowledge receipt of the message. Figure 3: Centralized Deadlock Detection. Figure 4: False Deadlock. 5|Page
  • 6. DISTRIBUTED DEADLOCK Distributed: An algorithm for detecting deadlocks in a distributed system was proposed by Chaudy, Misra, and Haas in 1983. It allows that processes to request multiple resources at once (this speeds up the growing phase). Some processes may wait for resources (either local or remote). Cross-machine arcs make looking for cycles (detecting deadlock) hard. The algorithm works this way: When a process has to wait for a resource, a probe message is sent to the process holding the resource. The probe message contains three components: the process that blocked, the process that is sending the request, and the destination. Initially, the first two components will be the same. When a process receives the probe: if the process itself is waiting on a resource, it updates the sending and destination fields of the message and forwards it to the resource holder. If it is waiting on multiple resources, a message is sent to each process holding the resources. This process continues as long as processes are waiting for resources. If the originator gets a message and sees its own process number in the blocked field of the message, it knows that a cycle has been taken and deadlock exists. In this case, some process (transaction) will have to die. The sender may choose to commit suicide or a ring election algorithm may be used to determine an alternate victim (e.g., youngest process, oldest process). Deadlock prevention An alternative to detecting deadlocks is to design a system so that deadlock is impossible. One way of accomplishing this is to obtain a global timestamp for every transaction (so that no two transactions get the same timestamp). When one process is about to block waiting for a resource that another process is using, check which of the two processes has a younger timestamp and give priority to the older process. If a younger process is using the resource, then the older process (that wants the resource) waits. If an older process is holding the resource, the younger process (that wants the resource) kills itself. This forces the resource utilization graph to be directed from older to younger processes, making cycles impossible. This algorithm is known as the wait-die algorithm (Figure 5). An alternative method by which resource request cycles may be avoided is to have an old process preempt (kill) the younger process that holds a resource. If a younger process wants a resource that an older one is using, then it waits until the old process is done. In this case, the graph flows from young to old and cycles are again impossible. This variant is called the wound-wait algorithm (Figure 6). 6|Page
  • 7. DISTRIBUTED DEADLOCK Figure 5: Wait-die Algorithm. Figure 6: Wound-wait Algorithm. 7|Page
  • 8. DISTRIBUTED DEADLOCK Conclusion: Deadlock is the state of permanent blocking of a set of processes each of which is waiting for an event that only another process in the set can cause. However, handling of deadlocks in distributed systems is more complex than in centralized systems because the resources, the processes and other relevant information are scattered on different nodes of the system. ……………………………………………………………….X…………………………………………………………………… 8|Page